Recessed handle for structural member

ABSTRACT

A recessed handle for a support member, e.g., a rear plate of an electrical equipment cabinet, includes a depression in one surface of the member and a rod extending across the depression inwardly of the surface but above the bottom surface of the depression.

This is a divisional application of application Ser. No. 09/005,454filed Jan. 12, 1998, now U.S. Pat. No. 6,005,195.

BACKGROUND OF THE INVENTION

This invention relates to equipment mounting structures, andparticularly to such structures including cabinets, racks, frames andthe like for removably housing circuit board packages used fortelecommunications purposes.

In telecommunication networks, changes are constantly occurring, both inthe subscribers connected to the network and to the services provided tothe various subscribers. For accommodating rapid changes, the recentpractice has been to terminate subscriber communication lines, e.g.,metal wires and optical fibers, on circuit board packages removablyhoused within equipment shelves. The shelves, in turn, are mounted onvarious mounting structures, referred to as racks or frames and thelike, which, in turn, can be mounted within enclosed cabinets. Thecircuit board packages include various electrical and/or opticalcomponents for processing signals arriving at the circuit boardpackages, and the mounting structures provide means for housing thecircuit board packages and include cables for routing signals andelectrical power to, between and from the various circuit boards.Changes in the network are readily achieved by replacing various circuitboard packages or changing the signal routing therebetween.

For greatest flexibility of use, design standards have been establishedwhereby different circuit board package receiving shelves can beinterchanged with one another in the same and different mountingstructures located in a common telephone control office or differentcentral offices. A problem caused is that the design standards are oftenso complete and detailed that desired changes in the various componentsof the mounting structures, arising from experience with use of themounting structures or in the design of replacement structures, aredifficult to make within the existing standards.

The present invention addresses this problem primarily in the context ofproviding improved components for use in existing mounting structuresor, owing to advantages provided by the new components, for use in newmounting structures made according to new standards.

SUMMARY OF THE INVENTION

In general, mounting structures for which components are providedaccording to the present invention comprise a frame formed from a gridof support members, spaced apart .shelf-assemblies mounted on the framefor receipt of circuit board packages, and various cables more or lessfixed in place for conveying signals and power throughout the frame andany cabinet in which the frame is disposed.

According to the invention herein claimed, a handle is provided on onesurface of a structural member for grasping and handling the member, butin a manner not increasing the dimensions of the member forwardly of theone surface. A depression is formed in the one surface and a rod isprovided extending diametrically across the depression inwardly of theplanar surface but above the bottom surface of the depression. The rodis thus recessed within the surface but spaced from the depressionbottom wall for providing space for the hand of an attendant graspingthe rod.

BRIEF DESCRIPTION OF THE DRAWINGS

Some of the drawings are schematic and the various drawings are not tothe same scale.

FIG. 1 is an exploded view, in perspective, of an electrical equipmentmounting structure made in accordance with this invention, the structureincluding a rigid framework, shelf assemblies fixedly secured within theframework, and front and rear cabinet doors;

FIG. 2 is a perspective view of one of the shelf assemblies shown inFIG. 1 and showing certain structural elements;

FIG. 3 is an exploded view, in perspective, of the framework shown inFIG. 1 and two shelf assemblies mounted therein;

FIGS. 4-9 are figures relating to cable retaining clips wherein:

FIG. 4 is a view in perspective of one clip;

FIG. 5 is a side elevation of the clip shown in FIG. 3;

FIGS. 6 and 7 are partial sectional views of the sub-assemblyshown inFIG. 2 showing the clip shown in FIGS. 4 and 5 mounted in place. FIG. 5shows the clip ready for use, and FIG. 6 shows optical fibers and apower cable retained by the clip; and

FIGS. 8 and 9 are similar to FIGS. 4 and 5, respectively, but showinganother clip;

FIGS. 10-12 are figures relating to a recessed handle for ashelf-assembly member in accordance with this invention wherein:

FIG. 10 is a rear elevation of a cover plate for the shelf assembliesshown in FIG. 1;

FIG. 11 is a view, in perspective, of a portion of a frontwardly facingsurface of the cover plate shown in FIG. 10; and

FIG. 12 is a section taken along the line 12—12 of FIG. 10;

FIGS. 13 and 14 are perspective views of two shelf-assembly mountingbrackets shown in FIGS. 1-3; and

FIG. 15 is a front view of a shelf-assembly mounted within a frameworkof a mounting structure different from the one shown in FIGS. 1-3 andshowing the use of the bracket shown in FIG. 14 in an orientationdifferent from the orientation of the bracket as shown in FIGS. 1 and 3.

DESCRIPTION OF PREFERRED EMBODIMENTS

Electrical equipment mounting structures of the type which are in thepresent invention are known, and an example of one such structure isshown in U.S. Pat. No. 5,150,277 (Sept. 22, 1992), the subject matter ofwhich is incorporated herein by reference.

FIG. 1 herein shows an example of an electrical equipment mountingstructure of known type but of a recent design taking advantage ofexperience gained with the use of known mounting structures andcontaining various structural features taking pre-existing designstandards into consideration. The mounting structure includes a basicframework 10 comprising strong and rigidly secured together horizontaland vertical struts 12. Two shelf-assemblies 16 are shown mounted on theframework 10 with each shelf-assembly 16 being provided with a rearcover plate 18. The framework 10 is part of a cabinet i.e., an enclosedstructure including front 21 and rear doors 22 mounted on the framework.

One of the shelf-assemblies 16 shown in FIG. 1 is shown by itself inFIG. 2. Also shown in FIG. 2 are four circuit board packages 22 of knowntype removably received within the shelf-assembly 16.

As shown in FIGS. 1 and 3, the shelf-assemblies 16 are secured to theframework 10 by mounting brackets. Pairs of cooperating brackets areused. FIG. 2 shows one bracket 24 (including lugs 25, hereinafterfurther described) of each of two pairs of brackets mounted on each wall26 of each shelf-assembly 16. In FIG. 1, only the lugs 25 of thebrackets 24 are visible, but FIG. 1 clearly shows the other bracket 28of two of the bracket pairs present. How the brackets 24 and 28 are usedfor mounting the sub-assemblies 16 within the framework 10 is shown inFIG. 3. Further discussion of the design and use of the brackets 24 and28 is provided hereinafter.

FIG. 2 additionally shows examples of cables typically routed within theshelf assemblies to and from circuit board packages 22 mounted thereon.Two types of cables are shown; one being cables 38 comprising aplurality of individual optic fibers 40, and the other being a powerfeeder 42 for conveying power to electrical and/or optical components(not shown) mounted on the circuit board packages and to power supplies(not shown) mounted within the electrical equipment cabinets.

Various improvements of structural elements used in the structures shownin FIGS. 1-3 are now described.

CLIPS

As mentioned, electrical and/or optical components mounted on thecircuit packs are interconnected to various other components within orexternal to the equipment mounting structures by means of cables ofelectrical wires and/or optical fibers. Some of the cables are more orless permanently fixed in place whereas others of the cables must beperiodically re-routed. Retainer means are used for fixing the cables inplace at various locations on the mounting structures and, particularlywith non-permanent cables, a need exists for a simple retaining meanswhereby a cable being routed can be quickly and firmly secured in placeat various spaced apart positions on the mounting structure and just assimply be detached from the retaining means.

A cable retainer clip 100 satisfying these requirements is shown inFIGS. 4-7. The clip 100 is shown by itself in FIGS. 4 and 5, at severallocations on the shelf assembly 16 shown in FIG. 2, and at a singlelocation ready for use, and in use, respectively, in FIGS. 6 and 7.

The clip 100 is designed to be resiliently bent with relatively greatdisplacements and many times without breakage or loss of strength. Tothis end, the clip is preferably of “spring tempered” stainless steel,e.g., of a steel commonly used in coil and leaf springs. Other materialscan be used, e.g., copper alloys or plastics, and, by way ofgeneralization, all such materials are referred to as “spring tempered”materials for indicating suitability for the function of the clip 100shortly to be described.

The clip 100 can be mounted in any number of orientations but, forconvenience of description, it is assumed to be so oriented that theterms “horizontal” and “vertical” can be used for descriptive purposes.

The clip 100 (FIGS. 4 and 5) has a generally strip-like shape, i.e., itis relatively narrow and long along an axis 102 (FIG. 5) of elongation.Other length to width shapes are possible but, as to be described, theclip functions as a leaf spring and the strip-like shape is generallypreferred. With the clip axis 102 horizontally oriented, the clip can bedescribed as including three successive steps 104, 106 and 108 with thesteps succeeding one another both horizontally and vertically. Thus, afirst step 104 having first and second oppositely disposed ends 110 and112 extends horizontally with the second step end 112 connected by afirst vertical plate 114 to a first end 116 of a second step 106. Asecond end 118 of the second step 106 is connected, in turn, by a secondvertical plate 120 to a first end 122 of a third step 108.

Dependent from the first end 110 (FIG. 5) of the first step 104 is afirst cam member 124, and a second cam member 126 is dependent from thesecond end 128 of the third step 108. Each cam member 124 and 126 issemicircular in cross-section. Of importance, but being a matter ofselection dependent upon the expected use of the clip 100, is thespacing of the bottom surfaces of the cams 124 and 126 relative to thesecond step 106. In this embodiment, the first cam 124 is secureddirectly to the first end 110 of the first step 104 and is of such sizethat the bottom surface 130 of the first cam 124 extends (in the clipunmounted condition shown in FIGS. 4 and 5) slightly below the bottomsurface 132 of the second step 106.

The second cam 126 is disposed at some distance below the third step 108and is connected to the second end 128 thereof by a vertical plate 134.The bottom surface 136 of the second cam 126 thus extends well below thebottom surface 130 of the first cam 124.

A feature of the clip 100 is that, in a preferred use, the clip ismounted at a corner 140 (FIGS. 2 and 6) of a shelf brace member 142 andis effective for removably securing spaced apart cables against (FIG. 6)transverse upper (146) and side (144) surfaces of the member.

To this purpose, the clip second step 106 (FIG. 4) is convenientlyprovided with an opening 150 by means of which the clip can be firmlyattached to the upper surface 146 by means of a single machine screw 152(FIG. 6). As shown, the clip 100 is positioned adjacent to the membercorner 140 such that while the second step 106 extends along the uppersurface 146 of the member 142, the portion of the clip 100 from thesecond end 118 of the second step 106 to the second cam 126 connected tothe clip third step 108 is disposed along the member side surface 144.The vertical plate 120 (FIG. 5) between the second step 106 and thethird step 108 extends generally parallel to the side surface 144 of themember 142. Contact between the clip vertical plate 120 and the sidesurface 144 prevents rotation of the clip around the single screw 152used to secure the clip 100 to the member 142.

As previously mentioned, the bottom surface 130 of the cam 124 extends,in the unmounted (FIG. 5) and non-flexed condition of the clip, belowthe bottom surface 132 of the second step 106. However, when the clip100 is mounted on the member 142 with the upper surface 146 of themember extending parallel to the second step 106, the firm fastening ofthe second step 106 to the surface 146 causes a slight upward tilting ofthe first step 104 relative to the second step 106. FIG. 6 shows theclip 100 securely mounted on the structural member 142, but the degreeof tilting of the first step 104 is so small that the first step 104appears parallel to the surface 146. The slight tilting which doesoccur, i.e., a flexure of the first step 104, provides a spring forcepressing the cam member 124 against the surface 146. This is discussedfurther hereinafter.

The location of the clip cam 126 relative to the side surface 144 of thestructural member 142 is also shown in FIG. 6. In this instance, the cam126 is spaced from the surface 144 by, essentially, the length of thethird step 108.

A preferred use of the clip 100 is now described. The clip 100 is firstmounted on the member 142, as shown in FIG. 6, and various cables andthe like are thereafter disposed between the clip 100 and the member twosurfaces 144 and 146, as shown in FIG. 7. (Alternatively, but nottypically, cables can be first placed against one or both membersurfaces and then clamped in place as the clip is mounted in place.)

Preferably, however, with the clip fixedly in place, a plurality ofrelatively small diameter light guide fibers 40 (FIG. 7) are forcedinwardly of the clip 100 by disposing one or more cables on the memberupper surface 146 and extending perpendicular to the axis 102 of theclip 100 and urging the fiber(s), e.g., by hand, against the curvedouter surface of the cam 124. The cam 124 is thus lifted above thesurface 146 allowing the fiber(s) 40 to pass underneath the cam and intothe space encompassed by the first step 104. The upward movement of thecam 124 further tilts and flexes the step 104 and, upon passage of thefiber inwardly of the cam 124, pressure of the flexed leaf spring clipforces the cam 124 back into contact with the member surface 146. Thesmall optical fibers are thus retained within the clip 100. Similarly,because of the circular shape of the surface of the cam 124 facinginwardly of the clip, optical fibers otherwise securely retained withinthe clip can easily be removed, e.g., again by hand, by forcing thefibers laterally against the inner surface of the cam for lifting thecam for removal of the fibers.

Of importance, owing to the relatively small diameter of optical fibers,the amount of flexure of the clip necessary for the passage of thefibers beneath the cam 124 is relatively small. Accordingly, thepressure applied against the fibers is sufficiently small for avoidingdamage of the fibers.

The other end of the clip containing the cam 126 serves, in thisembodiment, a slightly different purpose in that, instead of retainingdelicate and small diameter optical fibers, it is intended to retain arelatively large and quite rugged power cable 42. In this instance,owing to the rather large size of the cable, it is preferable that thecam 126 be spaced from the member side surface 144, as shown in FIG. 6,to provide an opening for initial receipt of the power cable partiallyinwardly of the clip. However, the dimensions of the clip relative tothe power cable are such that a relatively large force is then requiredto force the cable fully inwardly of the space defined by the clipvertical plate 134, the third step 108 and the structural member surface144. Although the cam 126 does not thereafter close the space containingthe cable, the spring pressure extended by the flexed clip retains thepower cable 42 in place in reliance upon friction between the typicallyrough surface of the power cable and the clip and structural memberretaining surfaces.

While the power cable 42 is thus readily inserted into the clip spaceand firmly retained thereon, the cable is similarly quite easily removedfrom the clip.

Another embodiment of a retainer clip 160 is shown in FIGS. 8 and 9.Here, three steps 162, 164 and 166 are present, but the first 162 andthird 166 steps are at equal levels above (FIG. 9) the second step 164.The first 162 and third 166 steps terminate in dependent cams 168, thebottom surfaces 170 of which are spaced below the bottom surface 172 ofthe second step 164.

In use, as shown in FIG. 2, the second step 164 is secured to acontinuous flat vertical surface 176 relative to which both clip steps162 and 166 (FIG. 9) are slightly flexed by contact by the two cams 168against the surface 176. Each step 162 and 166 and its attendant cam 168functions for retaining optical fibers as previously described inconnection with the cam 124 of the clip 100 (FIGS. 6 and 7).

HANDLE

As previously noted, in connection with the mounting structure shown inFIG. 1, separate removable shelf-assemblies 16 are included within theframe 10. Typically, the shelf-assemblies are assembled while separatefrom the frame and closed with rear covers 18. The covers are relativelylarge and awkward to handle and an improvement in the covers is thatthey be provided with handles on the rear facing surfaces thereof. Owingto various design standards, however, nothing can be placed on thecovers which projects rearwardly of the cover rearwardly facing surface.Accordingly, and in accordance with this invention, quite simple butstrong handles are provided recessed within the rearwardly facingsurfaces of the rear covers.

FIG. 10 shows a typical rear cover 18 in accordance with existing designstandards and including a pair of recessed handles on the rearwardlyfacing surface 202 of the cover 18. FIG. 10 shows the rearwardly facingsurface 202, and FIGS. 11 and 12 show a portion of the opposite(frontwardly facing) surface 204 of the cover.

The cover 18 is basically a flat plate of metal having a thickness, inone typical cabinet, of 1.54 mm, a length of 715 mm and a width of 499mm. The plate weighs around 2 kg and, because of its relatively largesize, includes four right-angled stiffening braces 208, portions of twoof which are shown in FIGS. 11 and 12. The braces 208 run the entirelength of the cover plate (as indicated in FIG. 10), are mounted on thefrontwardly facing surface 204 of the plate, and have a projectingheight from the plate surface 204 of 14 mm.

For providing two recessed handles on the rear surface 202 of the coverplate, two circular depressions 210 are formed by known sheet metalforming processes, e.g., deep drawing, and comprise a portion of asphere having a radius of 72 mm and an inside depth of 20 mm. Adding thethickness of the cover plate, the depressions 210 project about 21.5 mminwardly of the plate rear surface 202. The depressions 210 thus have aprojecting height relative to the front surface 204 of the cover plateof 18.5 mm, which is greater than the height of the braces 208. However,the amount of space provided between the inside surface of the cover andcomponents within the shelf- assembly is adequately large to accommodatethe space taken-up by the depressions.

Each depression 210 has a generally continuous spherical wall except for(FIG. 12) a pair of oppositely disposed circular holes 214 (of 5 mmdiameter) entirely through the depression wall and spaced (centers ofthe holes) 4 mm from the rear surface 202 of the cover plate. Astainless steel rod 216, e.g., of 3.9 mm diameter, extends between andthrough each hole, thus spanning the depression and spaced from thedepression inner bottom surface by a distance of around 17 mm and havinga length, between the depression wall holes 214, of around 95 mm.

The depression and rod dimensions are selected for use of the rods 216as hand graspable handles. The depths of the depressions 210 and thespacing of the rods 216 from the depression bottoms admit entry of ahandler's fingers inwardly of the depressions and “forwardly” of therods. Of significance, the rods 216 are fully recessed inwardly of therear surface 202 of the cover so as not to increase the rearwardlyextending dimensions of the cover. Additionally, the depressions do notweaken the cover plate and, being substantially continuous (the two rods216 substantially filling and closing the depression wall holes 214),there is little impairment of the enclosing function of the cover 18.

For firmly securing the rods 216 in place, bores 220 (FIG. 11) are cutinto the braces. Each bore 220 extends entirely through the bracevertical wall 221 and continues as a groove 220a along the surface 224of the brace horizontal wall 226. At each depression 210, the axes 228of the brace bores 220 on opposite sides of the depression are preciselyaligned and bisect the depression. Accordingly, a handle rod 216 can bethreaded along each pair of aligned bores 220 with the rod ends beingsnap-fitted and firmly locked in place within the brace grooves 220 a.

MOUNTING BRACKETS

As shown in FIGS. 1-3, the shelf-assemblies 16 are mounted in thecabinet framework 10 by means of various mounting brackets. Of interestherein are the two previously referred to brackets 24 and 28. Thebrackets 24 are secured (FIG. 2) directly to side walls 26 of the shelf-assemblies 16; the brackets 28 are secured (FIG. 1) directly to theframework 10; and the brackets 24 are secured (FIG. 3) to the brackets28 for securing the shelf assemblies to the framework 10. Preferably,all the various securings are by means of standard nuts and screws.

A bracket 24 is shown by itself, in perspective, in FIG. 13. The bracket24 comprises an elongated strip 300 of metal having two screw receivingholes 302 therethrough, and a pair of (the aforementioned) mounting lugs25 disposed at opposite ends of the strip 300 and extending at rightangles to the strip. Each lug 25 has a hole 306 therethrough includingan internal screw thread. Most simply, a threaded nut (also identifiedby numeral 306) is secured in place, as being press fitted into acircular opening through the lug.

The bracket 24 is secured to a shelf-assembly 16 as shown most clearlyin FIG. 2. The bracket lugs 25 are passed through slots (not visible) inthe side walls 26 of the assemblies and are secured to the insidesurfaces of the walls 26 by means of flat-headed screws 306 a passingthrough counter-bored screw openings through the side walls 26. Thescrews 306 a are tightly screwed into the nuts 306 mounted on thebracket lugs 25. In FIG. 2, the external heads of the screws 306 a arejust visible on the external surface of the right-hand wall 26 of theassembly 16, and the shanks of four screws 306 a are visible on theinside surface of the left-hand side wall 26 of the assembly.

When the brackets 24 are so screwed in place, the elongated strips 300of the brackets project laterally away from the assembly side walls 26and can be screwed (FIG. 3) to the brackets 28 secured to the framework10. One bracket 28 is shown, in perspective, by itself in FIG. 14. Thebracket 28 is a right-angled metal member including a first elongatedstrip 320 having a “peaked” side edge 322 joined, along a common edge323, to a second elongated strip 324 having a straight edge 326. By“peaked” is meant that spaced along otherwise straight portions of theedge 322 are a number of spaced apart projections 322 a. The purpose ofthe spaced apart projections is described hereinafter. The projections322 a are quite rigid and strong extensions of the strip 320 which, ineffect, has a greater width at the locations of the projections 322 athan at the locations at the gaps between the projections.

As mentioned, the right angle brackets 28 are mounted on the framework10. This is shown in FIG. 3 where the bracket 28 straight edged secondstrips 324 are shown to be secured to inwardly facing surfaces 12 a ofvertical struts 12 of the framework. The bracket 28 elongated strips 320are also clearly visible in FIG. 1 except that the projections 322 a(FIG. 14) on the brackets 28 are hidden by the front edges 26 a of theshelf-assembly side walls 26. Also hidden in FIG. 1 are the elongatedstrips 300 (FIG. 13) of the brackets 24 secured directly to theshelf-assembly side walls 26. (In FIG. 1, the lugs 25 of the brackets 24are visible).

As previously mentioned, portions of the mounting structure shown inFIG. 1 are different from previously made structures but are so designedthat, for example, the shelf-assemblies 16 can be used in the earliermade mounting structures. In such use, the design standards are suchthat, except for a very narrow portion of the front end of theshelf-assembly assembly side walls 26, nothing can be mounted on theside walls 26 which increases, to the smallest extent, the width of theshelf-assemblies. The design of the brackets 24 takes this restrictioninto account. Thus, the lugs 25 of the brackets 24 are not screwed toexternal surfaces of the walls 26, but extend through the aforementionedslots through the walls. The flat-headed screws 306 a, used for securingthe lugs 25 to the walls 26, are either completely recessed inwardly ofthe exterior surfaces of the walls 26 or, at worst, flush therewith.Thus, except for the laterally extending strips 300 of the brackets 24,which are disposed forwardly of the framework of the previously mademounting structures, the mounting of the brackets 24 on the shelfassembly side walls 26 in no way increases the width of theshelf-assemblies.

A feature of the brackets 28 is that they are multi-functional for use,in different orientations, in different mounting structures. As shown inFIGS. 1 and 3, for example, the straight edge strip 324 of the brackets28 is secured to a strut 12 of the framework 10, and the projections 322a are secured to the elongated strips 300 of the brackets 24 secured tothe shelf-assemblies 16. In this application, the full width of thepeaked strip 322 of the bracket is used.

In another application, as shown in FIG. 15, the orientation of thebracket 28 is changed such that the bracket straight edged strip 324 issecured directly to a shelf-assembly and the peaked strip 320 secureddirectly to a strut 12 of a framework 10 a. In this application, thefull width of the bracket peaked strip 320 is not used, but rather thebracket strip 320 is secured to the strut by means of screws 334 passingthrough openings 330 (FIG. 14) through the bracket strip 320 inwardly ofthe strip edge 322 and spaced from the projections 322 a. Theprojections 322 a thus project beyond the strut 12 and into spaces onrespective sides of the struts 12. Therein lies a problem. As indicatedin FIG. 15, a vertically extended channel 13 beyond each strut 12 (e.g.,between it and a forwardly projecting side wall 13 a of the mountingstructure shown) is used for the passage of various cables 40 some ofwhich exit the space for routing forwardly around the struts forextension to the shelf-assembly 16. For preventing blocking of the exitsfor the cables by the unused (in this application) width of the bracket,gaps are provided between the projections 322 a along the bracket edge322. Thus, while the projections 322 a can be provided on the bracket 28for providing it with the necessary dimensions for the application shownin FIGS. 1-3, the gaps between the otherwise unused projections 322 a ofthe brackets 28 permit use of the brackets 28 in the FIG. 15application. Provided the gaps between the projections 322 a are wideand deep enough to permit passage of exiting cables between adjacentprojections 322 a, and provided the projections 322 a are adequatelystrong for their mounting (FIGS. 1-3) function, the projections 322 acan have other shapes than the preferred shapes shown.

What is claimed is:
 1. In combination, a structural plate member of anelectrical equipment mounting structure and a handle mounted on saidplate member, said plate member having first and second oppositelydisposed surfaces, a depression in said plate member inwardly of said ofsaid first surface, said depression comprising a wall having a bottomsurface, said handle being within the depression and spaced entirelyinwardly from said plate member first surface and spaced from saiddepression bottom surface, said handle extending between and secured atoppositely disposed portions of said depression wall, said depressionwall having oppositely disposed first and second wall surfaces each ofwhich is an integral extension of respective said first and secondsurfaces of said plate member, ends of said handle extending into firstopenings through said depression wall, said handle ends being secured inplace beyond said depression wall, a pair of plate stiffening bracesdisposed on opposite sides of said depression, said handle ends beingsecured in place by engagement with said braces, said depression havinga rim integrally joined to said plate member first surface, and saidhandle consisting of a straight rod lying in a plane disposed betweensaid depression bottom surface and said rim.
 2. A combination accordingto claim 1 wherein said depression wall is spherical in configuration,and said rod extends diametrically across said depression.
 3. Acombination according to claim 2 wherein the dimensions of saiddepression, said rod, and the distance between said rod and saiddepression bottom surface are such as to allow grasping of the rod by auser's hand with the fingers of the hand extending inwardly of saiddepression and around said rod.
 4. In combination, a structural platemember of an electrical equipment mounting structure and a handlemounted on said plate member, said plate member having first and secondoppositely disposed surfaces, a depression in said plate member inwardlyof said first surface and having a bottom surface, said handle beingwithin the depression and spaced inwardly from said plate member firstsurface and from said depression bottom surface, said handle extendingbetween and entirely through oppositely disposed wall portions of saiddepression, a pair of plate stiffening braces disposed on opposite sidesof said depression, said handle having oppositely disposed ends securedin place by engagement with said braces, each of said stiffening bracescomprising two joined together transverse members, a first of saidtransverse members lying against said second surface of said platemember and a second of said transverse members facing towards saiddepression and projecting away from said plate member second surface, asecond opening extending entirely through said second transverse memberand continuing as a groove along a surface of said first transversemember, and one of said handle ends extending entirely through saidsecond opening through said second transverse member and into saidgroove in said first transverse member.